JPH1065544A - Digital signal processing unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a digital signal processing unit in which delay is prevented in the case of monitoring an input audio signal and occurrence of crosstalk during transmission and a deteriorated S/N are prevented. SOLUTION: A D/A converter 6 converts a 64fs /16 bit digital signal from an interpolation filter 5 into an analog signal. A ΣΔmodulation D/A converter 7 directly converts a 64fs /1 bit digital signal from a ΣΔ modulation A/D converter 2 into a monitor use analog signal. A changeover switch 8 selects the analog signal from the D/A converter 6 or the analog signal from the ΣΔ modulation D/A converter 7.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital signal processor for converting a high-speed 1-bit digital signal into a multi-bit digital signal when performing signal processing on the high-speed 1-bit digital signal obtained by sigma-delta modulation processing. About.

[0002]

2. Description of the Related Art Sigma Delta (ΣΔ) modulated high speed 1
The bit signal has a sampling frequency of 64 times 44.1 KHz and a data word length of 1 bit, as compared with a so-called multi-bit digital signal having a sampling frequency of 44.1 KHz and a data word length of 16 bits used in conventional digital audio. It has a very high sampling frequency and a short data word length, such as bits, and features a wide transmittable frequency band. Further, even with a 1-bit signal due to ΣΔ modulation, a high dynamic range can be secured in a conventional audio band (20 KHz) which is low with respect to an oversampling frequency of 64 times. By utilizing this feature, it can be applied to high-quality sound recorders and data transmission.

The circuit using the ΣΔ modulation processing itself is not a particularly new technology, and the circuit configuration is suitable for IC integration, and the accuracy of A / D conversion can be relatively easily obtained. It is often used inside a D converter. The ΣΔ modulated signal can be converted back to an analog audio signal by passing through a simple analog low-pass filter.

[0004]

By the way, in the A / D conversion system using the さ ら に Δ modulator, in order to reduce noise that is noise-shaped in a high frequency band and to thin out oversampled data, Although a digital filter is provided to increase the bit length, the number of taps of the digital filter increases as the quality of the A / D conversion system increases. For this reason, if an FIR filter having a constant group delay is used for the digital filter, the amount of delay generated by A / D conversion increases. Further, although the IIR filter has a small amount of delay, the group delay cannot be kept constant, which leads to deterioration of characteristics.

Further, considering a D / A conversion system for returning a ΣΔ modulated digital signal to an analog signal, oversampling is performed by interpolation using a digital filter in order to reduce the load on the analog filter for preventing aliasing noise. Therefore, the amount of delay increases as in the case of A / D conversion.

[0006] From the above, when monitoring the input signal, A
The use of a signal that has passed through the / D conversion and the D / A conversion increases the amount of delay, and unnaturalness due to delay occurs when monitoring the voice of one's own voice. The analog signal before input is output as an input monitor signal as it is.

However, when an analog signal is used as a monitor signal in this way, crosstalk or S
In some cases, the / N ratio deteriorated. Also, if the power supply of the A / D converter and the D / A converter is separated from each other, connecting a monitor path will cause a ground loop, which will cause troubles such as mixing of noise, resulting in high quality transmission. Could not be done.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a digital signal processing apparatus capable of preventing a delay when monitoring an input audio signal, and preventing crosstalk during transmission and deterioration of an S / N ratio.

[0009]

In order to solve the above-mentioned problems, a digital signal processing apparatus according to the present invention performs signal processing on a 1-bit digital signal from a sigma-delta modulator together with thinning processing and interpolation processing. The system is then switched between a system for converting to an analog signal afterwards and a system for directly converting to an analog signal for monitoring, so that a delay can be prevented when monitoring the input audio signal.

In order to solve the above-mentioned problems, a digital signal processing device according to the present invention performs signal processing on a 1-bit digital signal from a sigma-delta modulation unit together with thinning-out processing and interpolation processing, and then executes 1-bit processing again. In order to be able to switch between converting to a bit digital signal and then converting to an analog signal or directly converting to an analog signal,
This prevents delay when monitoring the input audio signal.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a digital signal processing device according to the present invention will be described with reference to the drawings.

This embodiment is a digital audio signal processing apparatus for subjecting a high-speed 1-bit digital audio signal obtained by performing sigma delta (ΣΔ) modulation processing to an analog audio input signal to signal processing such as recording / playback. is there. The ΣΔ modulation process performed here is
The sampling frequency f _s (= 44.
For example 64-fold to become example 64f _S of 1 KHz) is a sampling frequency.

[0013] As shown in FIG. 1, the digital audio signal processing apparatus, 64f _S / 1 bit of using the above sampling frequency 64f _S to the analog input signal supplied from the input terminal 1 subjected to ΣΔ modulation processing A ΣΔ modulation A / D converter 2 for outputting a digital audio signal;
And 64f _S / 1 bit to reduce the noise of the digital audio signal, also decimation filter 3 decimating the data rate f _S, and extending the bit length for example, 16 bits from the Δ modulation A / D converter 2, the decimation a digital signal processing circuit 4 for performing digital signal processing for recording / reproduction and the like to f _S / 16-bit digital audio signal from the filter 3, oversampling f _S / 16-bit digital audio processing signals from the digital signal processing circuit 4 D / a converter 6 and interpolation filter 5 for performing an interpolation process, the 64f _S / 16-bit digital signal from the interpolation filter 5 into analog signals for
A ΣΔ modulation D / A converter 7 for directly converting the 64 f _s / 1 bit digital signal from the ΣΔ modulation A / D converter 2 into a monitor analog signal, and a D / A converter 6 Analog signal and D / A converter 7 for ΣΔ modulation
Switch 8 for switching between analog signals from
And

The ΣΔ modulation A / D converter 2 has a configuration as shown in FIG. 2, and supplies an input audio signal via an input terminal 11 to an integrator 13 via an adder 12. The signal from the integrator 13 is supplied to the comparator 14, where it is compared with, for example, the midpoint potential (“0 V”) of the input audio signal and is quantized by one bit every one sample period. Here, the sample period of a frequency (sampling frequency) is a as described above for example 64f _S. This quantized data is supplied to the one-sample delay unit 16 and is delayed by one sample period. This delay data is supplied to the adder 12 through the 1-bit digital / analog (D / A) converter 17 and added to the input audio signal from the input terminal 11. As a result, the comparator 14 outputs a 1-bit digital audio signal obtained by ΣΔ modulation of the input audio signal from the output terminal 15.

[0015] decimation filter 3 is a digital filter, reducing the ΣΔ modulation A / D converter noise-shaped noise to a higher frequency band by 2, also the data rate of the oversampled data and f _S to 64f _S , And the bit length is changed from 1 bit to, for example, 16 bits.

When the decimation filter 3 is used at the subsequent stage of the ΣΔ modulation A / D converter 2, the number of taps must be increased, and the FIR which can configure a constant group delay is required.
The amount of delay generated by the filter increases. Further, when the IIR filter is used, the delay amount can be reduced, but the group delay cannot be kept constant, so that the characteristics deteriorate.

The digital signal processing circuit 4 has a configuration as shown in FIG.
_{The S} / 16-bit digital signal is subjected to signal processing for recording / reproduction, for example, signal processing in the amplitude direction such as fade processing, equalization processing, and mixing processing.

For example, the fade processing includes a fade-out processing for gradually lowering the level of the reproduced audio signal with time, and a fade-in processing for gradually increasing the level of the audio signal from zero level. In addition, there is a cross-fade process in which a fade-out process and a fade-in process are performed so as to cross within the same time.

The case where the digital signal processing circuit 4 performs a fade-out process on the output signal of the decimation filter 3 will be described.

When a control signal designating the start timing and speed of the fade-out process is supplied to the control signal input terminal 20, the control signal is supplied to the control circuit 21 and an arbitrary fade-out signal is generated. When the fade-out signal is supplied to the coefficient generator 22, a coefficient for gradually lowering the level of the audio signal to zero level is generated, and the coefficient is supplied to the multiplier 23.

[0021] Thus, the fade-out digital processing signals f _S / 16-bit level of the audio signal is controlled by the coefficient from the coefficient generator 22 from the multiplier 23 to the interpolations filter 5 is supplied.

It is also possible to perform a fade-in process for gradually increasing the level of the audio signal from the zero level by reversing the order of generation of the coefficients by the coefficient generator 22, for example.

The interpolation filter 5 performs interpolation processing for oversampling on the digitally processed signal of f _s / 16 bits from the digital signal processing circuit 4.

This interpolation filter 5 is also a digital filter, and outputs the filter output to a D /
When the D / A conversion is performed by the A converter 6, the delay amount becomes large as in the case of the A / D conversion.

When monitoring the input signal input to the digital signal processing device, the coefficient in the digital signal processing circuit 4 is adjusted, and the digital signal processing output sound is controlled by the D / A converter 6 and the changeover switch 8. From the output terminal 9 via the monitor. However, here, as described above, a sound having a large delay amount after the A / D conversion and the D / A conversion is monitored.

Therefore, AＡD modulation A / D converter 2
It is also conceivable that an analog signal before entering the / D conversion is used as an input monitor signal as it is.

However, in this method, since an analog signal is used, crosstalk and deterioration of the S / N ratio are caused during transmission. Also, the A / D conversion part and the D / A
If the power supply of the conversion part is separated, connecting a monitor path causes a ground loop, which causes troubles such as mixing of noise, and high-quality transmission cannot be performed.

Therefore, in this digital signal processing apparatus, the 64 f _S / 1 bit digital signal from the ΣΔ modulation A / D converter 2 is directly D / A converted by the ΣΔ modulation D / A converter 7 to obtain an input signal. Used as a monitor signal for

The ΣΔ modulation A / D converter 7 includes a decimation filter 3 which is often constituted by an FIR digital filter, and an interpolation filter 5.
The amount of delay due to conversion is very small as compared with. For this reason, 64 f _S / 1, which is the output of the ΣΔ modulation A / D converter 2,
The bit digital signal is used directly for monitoring the input signal.

Specifically, the signal is converted into an analog signal through a D / A converter 7 for ΣΔ modulation, and is converted into an analog signal by a normal D / A converter 6.
And the switch 8 is used.

In such a configuration, the decimation filter 3 and the interpolation filter 5 occupy a large part of the amount of delay between input and output, and digital signal processing such as recording / reproducing of the system is performed in any manner. since no longer be ignored by, by using for direct monitoring 64f _S / 1-bit digital signal from the ΣΔ modulation a / D converter 2 as described above, very few monitor signal of the delay amount is obtained.

As described above, according to the digital audio signal processing apparatus shown in FIG. 1, the A / D conversion and the D / A conversion can be performed at the time of overdubbing such as recording a new signal while monitoring the recorded signal. Without monitoring a sound with a large delay amount after the conversion, the 64 from the ΣΔ modulation A / D converter 2
The f _S / 1-bit digital signal so monitored after converting into an analog signal by ΣΔ modulation D / A converter 7 can monitor the delay amount of the minimum. For this reason, even if you monitor your own voice, the unnaturalness due to the delay is eliminated.

Further, since the monitor sound can be transmitted digitally, the characteristics do not deteriorate even in long-distance transmission, and the crosstalk and the S / N ratio do not deteriorate.

When the power supply of the A / D conversion section and the D / A conversion section are separated, a ground loop is generated when the monitor path is connected, but the ground loop can be easily cut off using a photocoupler or the like. it can.

In the digital audio signal processing apparatus shown in FIG. 1, a digital audio signal is converted into an analog audio signal, and then an analog audio signal from the D / A converter 6 or a .SIGMA..DELTA. Since the analog audio signal from the D / A converter 7 is switched, the changeover switch 8
May cause signal degradation.

Therefore, the present invention may be applied to a digital audio signal processing device as shown in FIG. 4 and a digital audio signal processing device as shown in FIG. 4 and 5, the same components as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

First, the digital audio signal processing device shown in FIG. 4 will be described. In this digital audio signal processing device, the signal between the digital signal processing circuit 4 and the interpolation filter 5 and the ΣΔ modulation A
Switching switches 31a and 31b for switching digital signals are inserted between the / D converter 2 and the ΣΔ modulation D / A converter 7, and the D / A converter 6 and the ΣΔ modulation D / A converter are inserted. 7 is only supplied to the analog adder 32.

Therefore, the analog audio signal output from the output terminal 9 by the digital audio signal processing device shown in FIG. 4 has a higher quality than the analog audio signal output by the digital audio signal processing device shown in FIG. Will be good.

In the digital audio signal processing device shown in FIG. 5, a changeover switch 31a for switching a digital signal is provided only between the interpolation filter 5 and the D / A converter 6. This is the same as FIG.

Another example is a digital audio signal processing device as shown in FIG. In FIG. 6 as well, components having the same configuration as in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

In the digital audio signal processing device shown in FIG. 6, the digital signal output of the interpolation filter 5 is input to the ΣΔ modulator 6 Σ.
Δ modulation output (64 f _s / 1 bit digital audio signal) and monitor 64 from Σ Δ modulation A / D converter 2
f _S / 1 bit digital audio signal is switched by the digital signal switch 34,
The signal is supplied to a D / A converter 7 for ΣΔ modulation, converted into an analog audio signal, and output from an output terminal 9.

[0042]

According to the digital signal processing apparatus of the present invention, the 1-bit digital signal from the sigma-delta modulation means is directly converted into an analog signal by the second analog conversion means for sigma-delta modulation and is used as a monitor. To use
In monitoring an input audio signal, delay can be prevented, and crosstalk during transmission and deterioration of the S / N ratio can be prevented.

Further, according to the digital signal processing apparatus of the present invention, the 1-bit digital signal from the sigma-delta modulation means is subjected to signal processing with thinning-out processing and interpolation processing, and then converted again to a 1-bit digital signal. After that, it is possible to switch between converting to an analog signal or directly converting to an analog signal, so that when monitoring an input audio signal, delay is prevented, and crosstalk during transmission and deterioration of the S / N ratio are prevented. be able to.

[Brief description of the drawings]

FIG. 1 is a block diagram of a digital audio signal processing device as an embodiment of a digital signal processing device according to the present invention.

FIG. 2 is a block diagram showing a detailed configuration of a ΣΔ modulation A / D converter used in the digital audio signal processing device.

FIG. 3 is a block diagram showing a detailed configuration of a digital signal processing circuit used in the digital audio signal processing device.

FIG. 4 is a block diagram of another digital audio signal processing device to which the digital signal processing device according to the present invention can be applied;

FIG. 5 is a block diagram of another digital audio signal processing device to which the digital signal processing device according to the present invention can be applied.

FIG. 6 is a block diagram of still another digital audio signal processing device to which the digital signal processing device according to the present invention can be applied.

[Explanation of symbols]

2 ΣΔ modulation A / D converter, 3 decimation filter, 4 digital signal processing circuit, 5 interpolation filter, 6 D / A converter, 7 ΣΔ modulation D / A converter

Claims (5)

[Claims] 1. A sigma-delta modulation means for performing a sigma-delta modulation process on an input signal to output a 1-bit digital signal, a decimation processing means for performing a decimation process on the 1-bit digital signal from the sigma-delta modulation means, Signal processing means for performing digital signal processing on the thinned signal from the thinning processing means, interpolation processing means for performing interpolation processing on the processed signal from the signal processing means, and an interpolation signal from the interpolation processing means to an analog signal A digital signal processing apparatus comprising: first analog conversion means for converting; and second analog conversion means for directly converting the 1-bit digital signal from the sigma-delta modulation means to a monitor analog signal. . 2. The digital signal processing device according to claim 1, wherein an analog conversion signal from said first analog conversion means and an analog conversion signal from said second analog conversion means are switched and output. . 3. The apparatus according to claim 1, wherein one of the processed signal from the signal processing means and the one-bit digital signal from the sigma delta modulation means is selected and supplied to the interpolation processing means or the second analog conversion means. The digital signal processing device according to claim 1, wherein: 4. The method according to claim 1, wherein one of the interpolation processing signal from the interpolation processing means and the one-bit digital signal from the sigma-delta modulation means is selected, and the first analog conversion means or the second analog conversion is selected. 2. The digital signal processing device according to claim 1, wherein the digital signal is supplied to a means. 5. A sigma-delta modulation means for performing sigma-delta modulation processing on an input signal to output the one-bit digital signal, a thinning-out processing means for performing thinning processing on the one-bit digital signal from the sigma-delta modulation means. Signal processing means for performing digital signal processing on the thinned signal from the thinning processing means, interpolation processing means for performing interpolation processing on the processed signal from the signal processing means, and sigma processing for the interpolation processing signal from the interpolation processing means. Re-sigma delta modulation means for performing a delta modulation process to output a 1-bit digital signal; one of the 1-bit digital signal from the sigma-delta modulation means and the 1-bit digital signal from the re-sigma delta modulation means And an analog conversion means for converting a signal into an analog signal. Ijitaru signal processor.